Basic Theoretical Model and Sampling Criteria for Time-Interleaved Photonic Analog-to-Digital Converters

TL;DR

This paper introduces a basic model for time-interleaved photonic ADCs, analyzing their performance, noise factors, and sampling criteria, demonstrating their potential for high-speed, high-fidelity analog-to-digital conversion beyond traditional limits.

Contribution

It provides a foundational model, detailed analysis, and sampling criteria for TIPADC, advancing understanding of its performance and design considerations.

Findings

Photonic sampling enables ultra-high bandwidth conversion.

The minimum feasible back-end electronics bandwidth is half the sampling rate.

Various noise sources impact the effective number of bits in TIPADC.

Abstract

In this paper, we present a basic model for time-interleaved photonic analog-to-digital converter (TIPADC) and analyze its linear, nonlinear, and noise performance. The basic operation mechanism of TIPADC is illustrated and the linear performance is analyzed in frequency domain. The mathematical expressions and the output of the system are presented in each processing step. We reveal that photonic sampling folds the whole spectrum of input signal in a narrow band, which enables the analog bandwidth of a TIPADC to be much higher than the bandwidth of back-end electronics. The feasible regions of the system is obtained in terms of system frequency response, and a set of sampling criteria determining the basic requirements to the system are summarized for typical applications. The results show that the global minimum feasible bandwidth of back-end electronics is the half of single channel sampling rate when the bandwidth of photonic sampling pulse is comparable to input signal frequency. The amplitude and phase noise of photonic sampling pulse train, the thermal noise and shot noise of photodetection, and the quantization noise and aperture jitter noise of EADCs are investigated. The nonlinearity of TIPADC is also analyzed. The effect of different factors, such as the single channel sampling rate, the average optical power and the bandwidth of back-end electronics, on the effective number of bits of TIPADC is qualitatively and quantitatively discussed. The results explicitly show that TIPADC can perform high fidelity conversion to ultra-high speed analog signal and overcome the major performance limitations existing in traditional ADCs such as aperture jitter and bandwidth. The criteria deduced will be an effective supplement to the generalized sampling theorem in designing TIPADC.